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通过对GPS观测资料的数值模拟,获取1999~2001年青藏块体东北缘地区地壳水平运动的非震反位错模型,结合本区视应变场空间分布,研究活动块体及其边界断裂运动、变形特征及应力应变积累部位和强度.结果表明:① 9个活动块体呈现东向由偏北至偏南的整体性顺时针运动. 以祁连山——海原断裂为界,两侧块体间的左旋相对运动明显,由西向东呈现走滑兼NE-NEE向挤压;② 有20条断层段(多数呈压性)不同程度地阻碍块体间的相对运动,其中祁连山断裂中东段(包括与日月山——拉脊山断裂交汇区)及与海原、庄浪河断裂交汇区更有利于应变积累,日月山——拉脊山断裂与柴达木块体北边界交汇区也可能存在一定程度的应变积累;③ 所得活动块体运动速率及边界断裂对块体相对运动的锁定量较1993~1999年相应结果有所减弱. 相似文献
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目前研究地震动空间变化的主要方法是利用密集台阵(如SMART1台阵等)的强震观测记录进行统计分析,由于地震动观测资料的不足,因而缺少基岩及不同场地类别地震动相干函数模型. 本文利用数值方法了模拟理论地震图,进而研究采用震源位错模型的基岩随机地震动的空间变化规律,并考虑震源破裂速度、子源个数、震源深度和介质传播速度等因素的影响. 其具体思路为:首先对应于每个样本,用有限差分数值模拟方法计算弹性半空间近场地震动场,而后对所有样本的计算结果进行统计,给出了一个走滑断层情形下的近场基岩表面及沿基岩竖直方向水平分量地震动的相干函数模型. 相似文献
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简述了近年来我国学者在与地震学和地球内部物理学相关的实验岩石力学和构造物理学研究方面的进展.在此领域的进展主要体现在:大量实验以及数学模拟结果丰富了对岩石脆性破裂过程,特别是结构和介质非均匀条件下破裂过程的认识;在非均匀断层的摩擦行为与失稳成核方面取得了一些新结果,揭示了断层滑动行为的复杂性;在岩石脆塑性转换和塑性流变方面取得了一些新结果,特别是在下地壳和上地幔物质的流变性质方面取得了重要进展;在高温高压岩石物理方面取得了一批实验结果, 并应用于地球内部物质的组成和状态的研究.这些结果为深入理解地球内部物质的物理性质、变形机制及地震物理过程提供了有价值的参考资料. 相似文献
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在汪素云等利用全国地震台网资料所得结果的基础上, 补充了约5万条区域地震台网Pn波到时数据, 再次反演了中国及邻区Pn波速度横向变化和各向异性变化. 对比分析了研究区的地壳厚度分布、大地热流分布、新生代火山岩分布和高温、高压实验研究结果, 并探讨了中国及邻区Pn波速度结构的成因. 定量分析结果表明, Pn波速度与地壳厚度成正相关变化, 与大地热流成反相关变化. 根据Pn波速度随地壳厚度变化而估计的P波速度vP随压强p的变化率δvP/δp, 与(Matsushima和Akeni)由二辉橄榄岩包体的岩石实验所得结果非常接近. 在扣除了增厚地壳引起的压强增大对Pn波速度的可能影响后, 青藏高原地区的低Pn速度区更加显著. 低Pn速度区与新生代火山岩分布区有较好的一致性. 在几处波速各向异性显著的区域, 快波速方向与地壳最大主压应力方向和现代地壳运动方向一致, 可能与研究区上地幔顶部沿挤压方向的流动变形有关. 相似文献
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本文利用球体粘弹性地球模型研究唐山地震断层基于地壳分层的震后变形影响,计算四种不同类型的地球分层模型(均匀模型和三种地壳分层模型)产生的震后变形场,分析不同模型对地表变形的影响异同,定量研究了实际地壳分层模型与均匀地壳模型计算的地表变形差异.计算结果显示,相对均匀粘弹性地球模型,利用分层的地壳结构模型,计算的唐山地震断层附近区域震后28年积累的变形,两者最大差值水平方向可达20mm,垂直变形相差10mm左右.计算的结果显示地壳结构的差异对震后地表变形的影响很大,超过现有高精度测量技术的精度.如果利用该区的实测资料进行反演研究,必须根据实际地壳构造情况考虑地壳分层的影响. 相似文献
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地壳缩短导致青藏隆升造山是普遍的认识.然而,在青藏东部,越来越多的观测数据和研究支持了中下地壳流与隆升造山的关系.目前,地壳缩短造山机制和中下地壳流造山机制仍然处于争论之中.本文建立了二维黏弹塑性有限元模型,模拟了龙门山断层带的多个地震循环的应变与变形,探讨了无与有中下地壳流情况下,地壳地表的位移、速度与变形的分布和演化;以及有中下地壳流情况下,不同流动范围、速度与黏度对模型结果的影响;并结合地形变观测数据的约束,推测了青藏东缘中下地壳流的流动状态.模拟结果显示,通过对比有和无中下地壳流的模拟结果,发现青藏东部震间的地表垂向速度在变形样式及数值上存在较大差异,即存在地壳流的地表垂向抬升速率显著大于无地壳流;震间在龙门山断层西侧附近产生的垂向凸状隆起随中下地壳流的速度、黏度及通道长度的变化而变化.此外,本文研究结果对青藏其他地区可能存在的地壳流的研究也具有一定的参考意义. 相似文献
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应用地块构造几何学方法和原理,系统研究了山西断陷带北部构造区地块构造类型、结构和运动特征. 运用断块多米诺模型,通过断裂构造地貌分析对比,系统地讨论了断块变形、断陷盆地伸展运动特点,及其区域分布特征. 分析结果显示:① 以北西向断裂划分,由西向东分为西区段、中区段和东区段,相应的地壳伸展量分别为4.46 km, 2.80 km和1.86 km.。断块平均伸展量约为1 km. 计算结果与实际测量数据大致相同; ② 以恒山断块为界,山西断陷带北部构造区可分为南北两区, 两区地震活动水平不同,分别为M7和6M 相似文献
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国内外岩石破裂实验研究、实验场观测及理论模式研究等都表明 ,突变性变形是最可能的短期地震前兆 ,其主要特征是持续加速变形 .其中与地震相关的突变 ,称为前兆性突变 ,或简称为有震变形 ;发生突变性变形后若较长一段时间内没有相应的地震发生 ,则是无震变形 .本文研究的主要是有震变形的特征 .提起突变 ,自然可能会想到短暂的快速变化 ,甚至不应有太长的持续时间 .实际上 ,突变的内涵还取决于研究对象的时间和空间尺度 .对于地壳变形而言 ,持续时间在几分钟到几天范围的突变性变化 ,很可能是地震的短临前兆 ,也很可能属于自然环境的影响 .… 相似文献
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以2000年两次MW 6.5冰岛地震为例,利用近场地下水位的同震响应和震后响应约束孔隙模型参数,分析了孔隙回弹效应造成的地表变形大小和时间演化过程。首先利用数值模拟方法获得地震造成的孔隙压力变化和测井水位响应的时间序列,并以测井水位的同震阶跃幅值和震后水位恢复速率分别约束孔隙模型中的Skempton系数和扩散系数;然后基于孔隙弹性模型使用最优孔隙参数模拟震后孔隙回弹效应引起的地壳变形。结果显示:孔隙压力的同震响应控制着孔隙回弹引起的地壳变形,其变形速率与流体扩散系数呈正相关关系;孔隙回弹造成的变形以垂直向为主,且随时间快速衰减。因此,利用近场地下水位的同震响应和震后响应可以约束孔隙模型参数,为获取震后孔隙回弹机制所致的地壳变形提供依据。 相似文献
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IntroductionQinghai-Xizang(QingzangorTibetan)plateauisthemostremarkableactivecollisionbeltontheEarth.Itsaveragealtitudeis5km,itscrustthicknessupto70kmanditsareaabout7?05km2.Inrecenttwentyyears,withthegeophysicalobservationdatagettingmoreandmore,manydy-namicmodelsaboutcrustthickeningandTibetanuplifthavebeenputforward(Harrison,etal,1992;LI,1995;ZENG,etal,1994;ZHONG,DING,1996;XIAO,WANG,1998).Theycanbedividedintotwotypes.ThefirsttypecharacterizesthattheconvergencebetweenIndiaandEura-s… 相似文献
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青藏高原东缘的地壳结构是两种主流青藏高原隆升模式争辩的焦点之一.中下地壳流曾经被认为是高原东缘隆升的主要构造驱动力,但是中上地壳之间低阻低速层的发现及其与2008 MS8.0汶川地震良好的对应关系表明,高原东缘具有向东刚性挤出的可能性.然而大部分关于龙门山断裂的数值模拟仍建立在下地壳流的基础上,仅将低阻低速层作为断裂的延续或是弱化地壳物性参数的软弱层,而非能够控制块体滑动的"解耦层",也没有考虑到刚性块体变形中的断裂相互作用.本文建立了包含相互平行的龙门山断裂与龙日坝断裂的刚性上地壳模型,用极薄的低阻低速层作为块体滑动的解耦带,采用速率相关的非线性摩擦接触有限元方法,基于R最小策略控制时间步长,计算了在仅有侧向挤压力作用下,低阻低速层对青藏高原东缘的刚性块体变形和断裂活动的作用.计算结果显示,低阻低速层控制了刚性块体的垂直变形和水平变形分布特征.在侧向挤压力的持续作用下,在低阻低速层控制下的巴颜喀拉块体能够快速隆升,而缺乏低阻低速层的四川盆地隆升速度和隆升量均极小,隆升差异集中在龙门山断裂附近,使其发生应力积累乃至破裂.龙日坝断裂被两侧的刚性次级块体挟持着一起向南东方向运动,但该断裂的走滑运动分解了绝大部分施加在块体边界上的走滑量,使得相邻的龙门山次级块体的走滑分量遽然减少,也使得龙门山断裂表现出以逆冲为主,兼有少量走滑的运动性质.本文所得的这些计算结果显示了在缺乏中下地壳流,仅在低阻低速层解耦下刚性块体隆升过程及相关断裂活动,提供了青藏高原东缘刚性块体挤出的可行性,为青藏高原东缘隆升机制的研究讨论提供了重要依据. 相似文献
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ANALYSIS OF EVOLUTION OF THE RIYUESHAN FAULT SINCE LATE PLEISTOCENE USING STRUCTURAL GEOMORPHOLOGY 
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下载免费PDF全文 The northeastern margin of Tibetan plateau is an active block controlled by the eastern Kunlun fault zone, the Qilian Shan-Haiyuan fault zone, and the Altyn Tagh fault zone. It is the frontier and the sensitive area of neotectonic activity since the Cenozoic. There are widespread folds, thrust faults and stike-slip faults in the northeastern Tibetan plateau produced by the intensive tectonic deformation, indicating that this area is suffering the crustal shortening, left-lateral shear and vertical uplift. The Riyueshan Fault is one of the major faults in the dextral strike-slip faults systems, which lies between the two major large-scale left-lateral strike-slip faults, the Qilian-Haiyuan Fault and the eastern Kunlun Fault. In the process of growing and expanding of the entire Tibetan plateau, the dextral strike-slip faults play an important role in regulating the deformation and transformation between the secondary blocks. In the early Quaternary, because of the northeastward expansion of the northeastern Tibetan plateau, tectonic deformations such as NE-direction extrusion shortening, clockwise rotation, and SEE-direction extrusion occurred in the northeastern margin of the Tibetan plateau, which lead to the left-lateral slip movement of the NWW-trending major regional boundary faults. As the result, the NNW-trending faults which lie between these NWW direction faults are developed. The main geomorphic units developed within the research area are controlled by the Riyueshan Fault, formed due to the northeastward motion of the Tibet block. These geomorphic units could be classified as:Qinghai Lake Basin, Haiyan Basin, Datonghe Basin, Dezhou Basin, and the mountains developed between the basins such as the Datongshan and the Riyueshan. Paleo basins, alluvial fans, multiple levels of terraces are developed at mountain fronts. The climate variation caused the formation of the geomorphic units during the expansion period of the lakes within the northeastern Tibetan plateau. There are two levels of alluvial fans and three levels of fluvial terrace developed in the study area, the sediments of the alluvial fans and fluvial terraces formed by different sources are developed in the same period. The Riyueshan Fault connects with the NNW-trending left-lateral strike-slip north marginal Tuoleshan fault in the north, and obliquely connects with the Lajishan thrust fault in the south. The fault extends for about 180km from north to south, passing through Datonghe, Reshui coal mine, Chaka River, Tuole, Ketu and Xicha, and connecting with the Lajishan thrusts near the Kesuer Basin. The Riyueshan Fault consists of five discontinuous right-step en-echelon sub-fault segments, with a spacing of 2~3km, and pull-apart basins are formed in the stepovers.
The Riyueshan Fault is a secondary fault located in the Qaidam-Qilian active block which is controlled by the major boundary faults, such as the East Kunlun Fault and the Qilian-Haiyuan Fault. Its activity characteristics provide information of the outward expansion of the northeastern margin of Tibet. Tectonic landforms are developed along the Riyueshan Fault. Focusing on the distinct geomorphic deformation since late Pleistocene, the paper obtains the vertical displacement along the fault strike by RTK measurement method. Based on the fault growth-linkage theory, the evolution of the Riyueshan Fault and the related kinetic background are discussed. The following three conclusions are obtained:1)According to the characteristics of development of the three-stage 200km-long steep fault scarp developed in the landforms of the late Pleistocene alluvial fans and terraces, the Riyueshan Fault is divided into five segments, with the most important segment located in the third stepover(CD-3); 2)The three-stage displacement distribution pattern of the Riyueshan Fault reveals that the fault was formed by the growths and connections of multiple secondary faults and is in the second stage of fault growth and connection. With CD-3 as the boundary, the faults on the NW side continue to grow and connect; the fault activity time on the SE side is shorter, and the activity intensity is weaker; 3)The extreme value of the fault displacement distribution curve indicates the location of strain concentration and stress accumulation. With the stepover CD-3 as the boundary, the stress and strain on NW side are mainly concentrated in the middle and fault stepovers. The long-term accumulation range of stress on the SE side is relatively dispersed. The stress state may be related to the counterclockwise rotation inside the block under the compression of regional tectonic stress. 相似文献
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RESEARCH OF SEISMOGENIC STRUCTURE OF THE MENYUAN MS6.4 EARTHQUAKE ON JANUARY 21, 2016 IN LENGLONGLING AREA OF NE TIBETAN PLATEAU 下载免费PDF全文
下载免费PDF全文 On January 21 2016, an earthquake of MS6.4 hit the Lenglongling fault zone(LLLFZ)in the NE Tibetan plateau, which has a contrary focal mechanism solution to the Ms 6.4 earthquake occurring in 1986. Fault behaviors of both earthquakes in 1986 and 2016 are also quite different from the left-lateral strike-slip pattern of the Lenglongling fault zone. In order to find out the seismogenic structure of both earthquakes and figure out relationships among the two earthquakes and the LLLFZ, InSAR co-seismic deformation map is constructed by Sentinel -1A data. Moreover, the geological map, remote sensing images, relocation of aftershocks and GPS data are also combined in the research. The InSAR results indicate that the co-seismic deformation fields are distributed on both sides of the branch fault(F2)on the northwest of the Lenglongling main fault(F1), where the Earth's surface uplifts like a tent during the 2016 earthquake. The 2016 and 1986 earthquakes occurred on the eastern and western bending segments of the F2 respectively, where the two parts of the F2 bend gradually and finally join with the F1. The intersections between the F1 and F2 compose the right-order and left-order alignments in the planar geometry, which lead to the restraining bend and releasing bend because of the left-lateral strike-slip movement, respectively. Therefore, the thrust and normal faults are formed in the two bending positions. In consequence, the focal mechanism solutions of the 2016 and 1986 earthquakes mainly present the compression and tensional behaviors, respectively, both of which also behave as slight strike-slip motion. All results indicate that seismic activity and tectonic deformation of the LLLFZ play important parts in the Qilian-Haiyuan tectonic zone, as well as in the NE Tibetan plateau. The complicated tectonic deformation of NE Tibetan plateau results from the collisions from three different directions between the north Eurasian plate, the east Pacific plate and the southwest Indian plate. The intensive tectonic movement leads to a series of left-lateral strike-slip faults in this region and the tectonic deformation direction rotates clockwise gradually to the east along the Qilian-Haiyuan tectonic zone. The Menyuan earthquake makes it very important to reevaluate the earthquake risk of this region. 相似文献
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青藏高原地壳变形加厚机制一直是地学界研究争论的热点问题.青藏高原目前仍然处在持续向外扩张之中,因此青藏高原的边界地带作为高原向外扩张的最前缘地区代表了高原最新的变形状态,是研究青藏高原地壳变形加厚的关键地区.本文以一条穿过青藏高原东北缘祁连山与酒西盆地结合部的深地震反射剖面为基础,结合前人地质、地球物理资料,通过细致的地质构造解译,获得青藏高原东北缘祁连山与酒西盆地结合部位地壳变形以壳内滑脱带为界上、下解耦.滑脱带位于壳内低速层的顶部,深度14~24 km.滑脱带之上的地壳部分以一系列南倾、北冲,并向下终止于滑脱带的逆冲断裂变形为主,指示了青藏高原向北的扩张方式;滑脱带之下的地壳以Moho面作为变形标志,指示了复杂的挤压缩短变形.据此我们推测上、下地壳的解耦缩短变形对青藏高原东北缘地壳的变形加厚起到了决定性的作用,甚至在整个青藏高原地壳的变形加厚过程中都起到了重要作用. 相似文献
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在青藏高原的运动变形过程中,断层活动起着至关重要的作用.本文利用有限元数值模拟的方法,分别计算了在GPS做边界约束下青藏高原及周边区域的连续体模型和含断层的不连续体模型的运动状态和应力场分布.从连续性模型和非连续体模型的差异发现,断层存在与否很大程度上影响了青藏高原现代运动场的分布.主要体现在,断层的滑移运动(1)增加了青藏高原东西两侧的拉张趋势;(2)加大了青藏高原物质东移的速度;(3)改变了塔里木和柴达木盆地的运动状态.模拟结果显示,非连续模型的运动场分布与GPS观测结果吻合程度大大高于连续体模型结果,表明断层活动在青藏高原的运动学和动力学过程中起着重要的作用,在研究青藏高原的动力学机制中,必须考虑断层作用的影响. 相似文献
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库木库里盆地位于青藏高原北缘,与柴达木盆地一山之隔,是二者的过渡地带,也是高原主体部分向NE扩展的前缘地区;现今构造表现为被3条大型活动构造带(走滑的阿尔金断裂带、东昆仑断裂带和逆冲的祁漫塔格褶皱逆冲系)所夹持。因此,该盆地对于研究青藏高原北缘的构造活动性、活动历史,探讨高原的扩展模式具有十分重要的意义。虽然库木库里盆地南、北两侧均发育活动性很强的大型走滑断裂,但是在盆地中央发育1条大型背斜,走向NWW-SEE,与祁漫塔格褶皱逆冲系和柴达木盆地内的褶皱构造走向一致,说明盆地目前遭受NNE向的挤压。通过对盆地地形横、纵剖面和阶地展布形态的分析,得出背斜有自西向东扩展变形的特征;野外调查和测年结果显示,背斜东段冰川融水形成了大型冰水扇,形成年龄为(87.09±2.31)~(102.4±3.7)ka,进而获得背斜东段自晚更新世以来平均隆升速率的最大值为(2.78±0.28)~(3.28±0.28)mm/a。库木库里盆地整体的活动性很强,在构造上与其北边的柴达木盆地类似,都受控于阿尔金断裂南侧的NNE向的区域挤压作用。 相似文献
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GEOLOGICAL AND GEOMORPHIC EVIDENCE FOR DEXTRAL STRIKE SLIP OF THE HELAN SHAN WEST-PIEDMONT FAULT AND ITS TECTONIC IMPLICATIONS 下载免费PDF全文
下载免费PDF全文 LEI Qi-yun ZHANG Pei-zhen ZHENG Wen-jun DU Peng WANG Wei-tao YU Jing-xing XIE Xiao-feng 《地震地质》2017,39(6):1297-1315
The horizontal movement of the Helan Shan west-piedmont fault is important to determination of the present-day boundary between the Alashan and North China blocks as well as to the exploration of the extent of the northeastward expansion of the Tibetan plateau. Field geological surveys found that this fault cuts the west wing of the Neogene anticline, which right-laterally offset the geological boundary between Ganhegou and Qingshuiying Formations with displacement over 800m. The secondary tensional joints (fissures)intersected with the main faults developed on the Quaternary flood high platform near the fault, of which the acute angles indicate its dextral strike slip. The normal faults developed at the southern end of the Helan Shan west-piedmont fault show that the west wall of this fault moves northward, and the tensional adjustment zone formed at the end of the strike slip fault, which reflects that the horizontal movement of the main fault is dextral strike slip. The dextral dislocation occurred in the gully across the fault during different periods. Therefore, the Helan Shan west-piedmont fault is a dextral strike slip fault rather than a sinistral strike slip fault as previous work suggested. The relationship between the faulting and deformation of Cenozoic strata demonstrates that there were two stages of tectonic deformation near the Helan Shan west-piedmont fault since the late Cenozoic, namely early folding and late faulting. These two tectonic deformations are the result of the northeastward thrust on the Alashan block by the Tibet Plateau. The influence range of Tibetan plateau expansion has arrived in the Helan Shan west-piedmont area in the late Pliocene leading to the dextral strike slip of this fault as well as formation of the current boundary between the Alashan and North China blocks, which is also the youngest front of the Tibetan plateau. 相似文献
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现今地壳变形数据显示横跨龙门山断裂带的地壳缩短速率低于3 mm·a-1,如此小的地壳缩短速率与龙门山断裂带附近的长期地质造山(平均高程约4.5 km)形成强烈对比.我们构建并使用了一个二维平面应变黏弹塑性有限元模型来模拟龙门山断裂带的地震循环位移变化,从而探讨了短期变形与长期变形之间的关系.模型模拟了地震循环的各个阶段(震间加载期、同震瞬间和震后黏性松弛调整期)以及多个地震循环(万年尺度)的地表变形,揭示了变形在地震循环中是如何累积、释放、调整以及最终形成永久变形导致了造山.模拟结果显示,岩石圈流变结构以及断层几何形态均对地震循环的地表位移变化有着显著的影响.经过多个地震循环,青藏高原东缘整体产生水平缩短与增厚抬升,而四川盆地基本保持稳定,区域的水平缩短主要由断层位错及青藏东缘的缩短抬升来调解,造成了青藏东部与川西盆地的差异抬升.研究结果将地震循环时间尺度的短期变形与长期地质造山联系起来,帮助我们理解青藏高原东部的隆升机制. 相似文献
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本文对位于青藏高原东缘川滇构造区的贡山一绥江大地电磁测深(MT)剖面数据进行反演,获得沿剖面的深部电性结构,为研究喜马拉雅东构造结、川滇菱形地块与华南地块的构造变形特征、壳幔耦合关系、地块间接触关系以及相互作用等问题,提供电性结构的依据.研究发现:(1)电性结构揭示澜沧江断裂带和小金河断裂带为深大断裂带,控制着研究区的深部结构特征和形变机制;(2)澜沧江断裂带和金沙江断裂带之间的高阻体,可能是扬子古地块的残留部分;小金河断裂带和安宁河断裂带之间的高阻体,则是峨眉山大火山省喷发形成的冕宁一越西杂岩带;(3)在滇西地块、川滇地块和大凉山地块均存在低阻层,它们的介质属性有所不同,滇西地块下的低阻层"疑似"高热状态的岩浆囊,主要由缅甸弧向东俯冲运动引起的,中上地壳的高热状态使地块的活动性增强;川滇地块内部的壳内低阻层的成因为:理塘断裂带和小金河断裂带之间的地表低阻层由破碎带充水所致,而金沙江断裂带和理塘断裂带之间的中地壳低阻层可能是由局部熔融物质或含盐流体导致的,其为壳内物质运移的通道.从而在地下物质发生大规模走滑运动的过程中起到引导作用;川滇地块东部和大凉山地块西部的壳内低阻层可能与地慢物质的上涌有关;马边断裂带附近的低阻体可能与破碎带变宽和破碎带内的流体有关. 相似文献